Abstract [en]

Summary Our knowledge on immortalization and telomere biology is mainly based on genetically manipulated cells analyzed before and many population doublings post growth crisis. The general view is that growth crisis is telomere length (TL) dependent and that escape from crisis is coupled to increased expression of the telomerase reverse transcriptase (hTERT) gene, telomerase activity upregulation and TL stabilization. Here we have analyzed the process of spontaneous immortalization of human T cells, regarding pathways involved in senescence and telomerase regulation. Two Nijmegen breakage syndrome (NBS) T cell cultures (S3R and S4) showed gradual telomere attrition until a period of growth crisis followed by the outgrowth of immortalized cells. Whole genome expression analysis indicated differences between pre-, early post- and late postcrisis cells. Early postcrisis cells demonstrated a logarithmic growth curve, very short telomeres and, notably, no increase in hTERT or telomerase activity despite downregulation of several negative hTERT regulators (e.g. FOS, JUN D, SMAD3, RUNX2, TNF-alpha and TGFbeta-R2). Thereafter, cMYC mRNA increased in parallel with increased hTERT expression, telomerase activity and elongation of short telomeres, indicating a step-wise activation of hTERT transcription involving reduction of negative regulators followed by activation of positive regulator(s). Gene expression analysis indicated that cells escaped growth crisis by deregulated DNA damage response and senescence controlling genes, including downregulation of ATM, CDKN1B (p27), CDKN2D (p19) and ASF1A and upregulation of CDK4, TWIST1, TP73L (p63) and SYK. Telomerase upregulation was thus found to be uncoupled to escape of growth crisis but rather a later event in the immortalization process of NBS T cell cultures.

Degerman, Sofie

Abstract [en]

Cellular immortalization is a major hallmark of cancer and is a multi-step process that requires numerous cell-type specific changes, including inactivation of control mechanisms and stabilization of telomere length. The telomeres at the chromosome ends are essential for genomic stability, and limit the growth potential of most cells. With each cell division, telomeres are shortened. Short telomeres may induce an irreversible growth arrest stage called senescence, or a growth crisis stage characterized by high genomic instability and cell death. Only very rarely do cells escape from crisis and become immortal, a stage that has been associated with the activation of the telomerase enzyme which can elongate and stabilize the telomeres.

The processes leading to senescence bypass, growth crisis escape and finally immortalization are only beginning to be elucidated. Most of our knowledge of the immortalization process is based on analyses of human fibroblast and epithelial cell cultures immortalized by genetic modification. In this thesis, spontaneously immortalized human T lymphocytes derived from patients with Nijmegen Breakage Syndrome and a healthy individual were used to identify critical events for senescence bypass and immortalization. Genetic analysis showed a clonal progression and non-random genetic changes including the amplification of chromosomal region 2p13-21 as an early event in the immortalization process. Telomere length gradually shortened at increasing population doublings and growth crisis was associated with critically short telomeres. The clone(s) that escaped growth crisis demonstrated a logarithmic growth curve, very short telomeres and, notably, no increase in telomerase activity or expression of the telomerase catalytic gene, hTERT. Instead, upregulation of telomerase activity and telomere length stabilization were late events in T lymphocyte immortalization. Escape from crisis was associated with downregulation of DNA damage response genes and altered expression of cell cycle regulators and genes controlling the cellular senescence program.

These data indicated that a number of layers of regulation are important in the process of immortalization and to provide further mechanistic detail, epigenetic analysis was carried out. Genome wide methylation array analysis identified early and step-wise methylation changes during the immortalization process. Interestingly, applying these findings to tumors of T cell origin revealed commonly methylated CpG sites in transformed cells. Deregulated gene expression of the polycomb complexes may have contributed to the epigenetic changes observed.

Taken together, our analysis of spontaneously immortalized T cell cultures identified several steps in the immortalization process including genetic, epigenetic, gene expression and telomere/telomerase regulatory events, contributing further insights to the complexity of cancer cell immortalization.